Welding :Welding Manufacturing Processes


Outline :Outline Introduction Welding Process Fusion Welding Arc Welding Resistance Welding Oxyfuel Welding Laser Welding Solid-State Welding Diffusion Welding Friction Welding Ultrasonic Welding Welding Metallurgy Welding Defects


Welding :Welding


Welding Applications :Welding Applications


Welding Process :Welding Process A concentrated heat source melts the material in the weld area; the molten area then solidifies to join the pieces together Sometimes a filler material is added to the molten pool to strengthen the weld


Types of Welding :Types of Welding Fusion Welding Use heat to melt the base metals and may add a filler metal Solid-State Welding Uses heat and pressure, or pressure alone, to join the metals; the temperature does not reach the melting point


Types of Welding :Types of Welding


Physics of Welding :Physics of Welding In fusion welding, a source of high-density heat energy raises the temperature of the surfaces enough to cause localized melting; if the heat density (power ÷ surface area) is too low, the heat is conducted away as fast as it is added and melting does not occur


Arc Welding :Arc Welding Uses an electric arc to heat and melt the work metals


Arc Welding :Arc Welding


Arc Welding :Arc Welding


Arc Welding :Arc Welding


Resistance Welding :Resistance Welding Uses heat and pressure to join metals; the heat is generated by resistance to an electrical current at the welding point


Resistance Welding :Resistance Welding Example of a resistance welding machine


Oxyfuel Welding :Oxyfuel Welding Uses a high-temperature flame from the combustion of acetylene and oxygen


Laser Welding :Laser Welding Uses a laser beam to melt the metals; can be used for deep, narrow welds


Laser Welding :Laser Welding Laser welding of a pipe


Diffusion Welding :Diffusion Welding Uses heat and pressure to join the metals by solid-state diffusion; the temperature is less than half the melting temperature atomic movement heat force force


Friction Welding :Friction Welding Uses pressure and frictional heat caused by mechanical rubbing, usually by rotation


Friction Welding :Friction Welding


Ultrasonic welding :Ultrasonic welding Uses rapid vibrations to break up surface films and heat the surfaces, allowing them to bond


Welded Joint :Welded Joint Fusion zone The area of base metal and filler metal that has been completely melted Weld interface A thin area of base metal that was melted or partially melted but did not mix with the filler metal Heat affected zone The surrounding area of base metal that did not melt, but was heated enough to affect its grain structure


Welding Metallurgy :Welding Metallurgy The base metal(s) and filler metal mix together during melting, forming an alloy when they solidify The solidification of the metals can be considered as casting a small amount of metal in a metal mold


Welding Metallurgy :Welding Metallurgy


Stresses and Distortion :Stresses and Distortion


Welding Defects :Welding Defects Cracks Fractures in the weld itself or in the metal adjacent to it Cavities Porosity and shrinkage voids; similar to casting defects Solid inclusions Nonmetallic solid material embedded in the weld metal


Welding Defects :Welding Defects Incomplete fusion A weld bead that does not fill the entire joint cross-section Imperfect shape / unacceptable contour A weld that does not have the proper shape for maximum strength Miscellaneous defects Arc strikes (damage from direct contact with an electrode), excessive spatter (drops of molten metal that solidify on the base parts), and others


Inspection and Testing :Inspection and Testing Visual inspection Visually examining the weld for surface defects Nondestructive evaluation Uses various methods that do not damage the specimen Destructive testing Methods in which the weld is destroyed during the test or to prepare the specimen


Visual Inspection :Visual Inspection Visual inspection checks for: conformance to dimensional specifications of the part design warpage cracks, cavities, incomplete fusion and other defects visible from the surface


Nondestructive Evaluation :Nondestructive Evaluation Dye-penetrant and fluorescent-penetrant tests use a dye or fluorescent substance to make small defects more visible Magnetic particle testing (limited to ferromagnetic materials) use small magnetic particles to find distortions in the magnetic field caused by defects Ultrasonic testing uses the transmission of sound through the specimen; discontinuities scatter or absorb the sound Radiographic testing uses X rays or gamma rays to detect flaws


Destructive Testing :Destructive Testing Mechanical tests use a weld joint in a conventional testing method, such as a tensile test or shear test Metallurgical tests involve creating metallurgical specimens, such as micrographs, to examine the features of the weld


Summary :Summary Fusion welding melts the material then allows it to solidify and join it together Solid-state welding uses pressure, and sometimes heat, to allow the metal to bond together without melting Welding allows the production of parts that would be difficult or impossible to form as one piece